1. Adaptive differentiation promotes intestinal villus recovery
- Author
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Takahiro E. Ohara, Marco Colonna, and Thaddeus S. Stappenbeck
- Subjects
Male ,Wound Healing ,Stem Cells ,Cell Cycle ,Adaptation, Biological ,Cell Cycle Proteins ,Cell Differentiation ,Epithelial Cells ,YAP-Signaling Proteins ,Cell Biology ,Cell Dedifferentiation ,Phosphoproteins ,General Biochemistry, Genetics and Molecular Biology ,Mice, Inbred C57BL ,Mice ,Models, Animal ,Animals ,Regeneration ,Female ,Intestinal Mucosa ,Molecular Biology ,Developmental Biology ,Adaptor Proteins, Signal Transducing ,Cell Proliferation ,Signal Transduction - Abstract
Loss of differentiated cells to tissue damage is a hallmark of many diseases. In slow-turnover tissues, long-lived differentiated cells can re-enter the cell cycle or transdifferentiate to another cell type to promote repair. Here, we show that in a high-turnover tissue, severe damage to the differentiated compartment induces progenitors to transiently acquire a unique transcriptional and morphological postmitotic state. We highlight this in an acute villus injury model in the mouse intestine, where we identified a population of progenitor-derived cells that covered injured villi. These atrophy-induced villus epithelial cells (aVECs) were enriched for fetal markers but were differentiated and lineage committed. We further established a role for aVECs in maintaining barrier integrity through the activation of yes-associated protein (YAP). Notably, loss of YAP activity led to impaired villus regeneration. Thus, we define a key repair mechanism involving the activation of a fetal-like program during injury-induced differentiation, a process we term "adaptive differentiation."
- Published
- 2021